WO2014117651A1 - High pressure gas remote conveyance and conversion system, method and use thereof - Google Patents

Abstract

A high pressure gas remote conveyance and conversion system, method and use thereof, the conveyance and conversion system comprising a power supply device (1), a high pressure gas generating device, a main high pressure gas conveyance pipe (5), and two or more remote users (2); the high pressure gas generation device comprises a high pressure gas pump (3) and a main high pressure gas tank (4); the power supply device (1) supplies power to the high pressure gas pump (3); and the main high pressure gas tank (4) is connected to the main high pressure gas conveyance pipe (5). Each remote user has two or more pressure reduction devices; the pressure reduction devices are connected to the main high pressure gas conveyance pipe (5) via branch high pressure gas conveyance pipes, and are connected to a power generation device. The high pressure gas pump transforms the excessive electrical energy of a power plant into the molecular potential of high pressure gas, and conveys the high pressure gas to a remote user in need of power, such that the remote user can utilize the high pressure gas to generate power, thereby solving the problem of power shortage.

Description

 High-pressure gas remote transmission conversion system, method and application thereof

 This invention relates to energy delivery, and more particularly to a high pressure gas remote delivery conversion system and its use. Background technique

 People's life and work are inseparable from electricity. The world without electricity is unimaginable. People's life without electricity will be boring. People's production without electricity will be stagnant, which will directly lead to the collapse of the entire social productivity. Electric energy is so important. At present, countries all over the world pay considerable attention to the development of electric energy. The more common power supply equipments are wind power, hydropower, thermal power and nuclear power. The substation supplies electricity from power supply equipment to people's lives and production. During the daytime, people's production activities require a lot of electricity, and the power supply of the substation is very tight. Sometimes it is even necessary to implement separate power supply to solve the problem of power shortage. At night, people's production activities require less electricity. At this time, the power supply of the substation is surplus. These surplus electric energy cannot be put into people's production and life, and finally lead to waste. If the wasted electric energy can be reused, it is undoubtedly better able to solve the electricity consumption during the daytime production and life. demand. However, it is more difficult to re-use the surplus of wasted electricity. It is necessary to solve the problem of energy conversion and energy transmission. Summary of the invention

 One of the technical problems to be solved by the present invention is to provide a high-pressure gas remote transmission conversion system capable of converting electric energy into other forms of energy for storage and transportation, and then converting it into electric energy, thereby partially solving the waste of electric energy and regional electricity consumption. The problem of shortage.

 The second technical problem to be solved by the present invention is to provide an application of a high-pressure gas remote transmission conversion system, which can convert electric energy into other forms of energy for storage and transportation, and then convert it into electric energy, thereby solving the electric energy waste and the region to some extent. The problem of shortage of electricity.

The third technical problem to be solved by the present invention is to provide a high-pressure gas remote transportation conversion method, which can convert electric energy into other forms of energy for storage and transportation, and then convert it into electric energy, thereby solving power waste and regional electricity to some extent. The problem of shortage. The fourth technical problem to be solved by the present invention is to provide a system for realizing remote energy storage power generation, which can convert electric energy into other forms of energy for storage and transportation, and then convert it into electric energy, thereby solving power waste and regional use to some extent. The problem of electric shortage.

 In order to solve one of the above technical problems, the technical solution of the present invention is: a high-pressure gas remote transmission conversion system, including a power supply device, a high-pressure gas generating device, a main high-pressure gas delivery pipe, and one or more remote users; The device includes a high pressure air pump and a main high pressure gas tank connected to the high pressure air pump, the power supply device supplies power to the high pressure air pump, and the main high pressure gas tank is connected to the main high pressure gas delivery pipeline; each of the remote users There is provided more than one step-down device, and the step-down device is connected to the main high-pressure gas conveying pipe through a branch high-pressure gas conveying pipe; the step-down device is connected to the power generating device. The power supply device of the present invention may be a power plant. In the case where the user uses a small power plant to generate power surplus at night, the high-pressure air pump is started, and the air source is continuously compressed into the main high-pressure gas tank for storage, thereby realizing the energy to the high-pressure gas molecule. Conversion of potential energy; The main high-pressure gas tank transports high-pressure gas to remote remote users through the main high-pressure gas transmission pipeline; these remote users who are in short supply can use the high-pressure gas in the pressure-relief equipment to generate electricity, thereby solving the shortage of electricity. The problem.

 As an improvement, the main high pressure gas delivery pipe is provided with a plurality of control tips.

 As an improvement, the branch high pressure gas delivery pipe is provided with a pressurizing device and a control trick. As an improvement, the remote user further includes more than one user collecting gas tank, the user collecting gas tank is connected to the main high pressure gas conveying pipeline through a high pressure gas recovery pipeline, and the high pressure gas recovery pipeline is provided with a supercharging device And control tips.

 As an improvement, the power generating device includes a wind power generator, a water tank, and a water turbine unit, and the pressure reducing device is connected to the water tank through a high pressure air pipe, and the water tank is connected to the water turbine unit through a water supply pipe, the water turbine unit and the water turbine The rotor of the wind turbine is linked. The installation of wind turbines is a development trend to solve the problem of electricity consumption in remote areas. However, wind turbines are subject to environmental constraints. When there is no wind or low wind speed, wind turbines cannot run electricity. The present invention will generate more power. The electricity generated by the locality is converted and transported, and finally applied to the wind power supply equipment to assist the wind power generator to generate electricity, thereby converting the molecular potential energy of the high pressure gas into electric energy.

In order to solve the above technical problem, the technical solution of the present invention is: an application of a high-pressure gas remote transmission conversion system, the high-pressure system delivery system including a power supply device, a high-pressure gas generating device, a main high-pressure gas delivery pipe, and more than one a remote user; the high-pressure gas generating device includes a high-pressure air pump and a main high-pressure gas tank connected to the high-pressure air pump, and the power supply device The high-pressure air pump supplies power, and the main high-pressure gas tank is connected to the main high-pressure gas conveying pipeline; each of the remote users is provided with more than one step-down device, and the step-down device passes through a branch high-pressure gas conveying pipeline and The main high pressure gas conveying pipeline is connected; the pressure reducing device is connected with the power generating device; after the high pressure air pump is powered by the power supply device, the air is compressed into the main high pressure gas tank for storage; the main high pressure gas tank releases the high pressure gas to the main In the high-pressure gas transmission pipeline, the main high-pressure gas transmission pipeline is used for remote transportation of high-pressure gas; the remote user introduces the high-pressure gas in the main high-pressure gas transmission pipeline into the pressure-reducing equipment through the branch high-pressure gas transmission pipeline; the remote user needs to generate electricity. At the time, the high-pressure gas in the step-down device is released and the power generation device is operated to generate electricity, thereby realizing the energy conversion, solving the waste of the surplus power of the power supply device and the shortage of power consumption of the remote user.

 As an improvement, the main high-pressure gas transmission pipeline is provided with a plurality of control tricks, and a high-pressure gas storage unit is formed between the two control gates, and the high-pressure gas storage unit can separately supply high-pressure gas to a remote user; When a high pressure gas leak occurs on the gas delivery pipe, the control door of the section is closed to ensure the safety of the main high pressure gas delivery pipe.

 As an improvement, the remote user further includes more than one user collection gas tank, the user collection gas tank is connected to the main high pressure gas delivery pipeline through a high pressure gas recovery pipeline; the remote user delivers the remaining high pressure gas to the user collecting gas In the tank, the high pressure gas in the user collection gas tank is returned to the main high pressure gas delivery pipeline through the high pressure gas recovery pipe.

 As an improvement, the power generating device includes a wind power generator, a water tank, and a water turbine unit, and the pressure reducing device is connected to the water tank through a high pressure air pipe, and the water tank is connected to the water turbine unit through a water supply pipe, the water turbine unit and the water turbine The rotor of the wind turbine is linked.

 In order to solve the above technical problem, the technical solution of the present invention is: a method for remotely transferring high-pressure gas, using a pipeline to remotely transport high-pressure gas, and setting a power generating device at a destination, and the high-pressure gas is working on the power generating device to make it Power generation.

 As an improvement, the power generating device includes a wind power generator, a water tank, and a water turbine unit, and the pressure reducing device is connected to the water tank through a high pressure air pipe, and the water tank is connected to the water turbine unit through a water supply pipe, the water turbine unit and the water turbine The rotor of the wind turbine is linked.

In order to solve the above technical problem four, the technical solution of the present invention is: a system for realizing remote energy storage power generation, comprising a power generation device, a high pressure gas generating device, a main high pressure gas delivery pipe, and one or more remote users; The generating device includes a high pressure air pump and a main high pressure gas tank connected to the high pressure air pump, and the power generating device supplies power to the high pressure air pump, the main high pressure a gas tank is connected to the main high pressure gas delivery pipeline; each of the remote users is provided with more than one user air supply tank, and the user gas supply tank is connected to the main high pressure gas transmission pipeline through a branch high pressure gas delivery pipeline The user air supply tank is connected to the energy conversion device; the energy conversion device includes a first energy storage power generation unit and a second energy storage power generation unit, and the first energy storage power generation unit includes a high pressure gas tank, two or more a first pool, a first turbine unit and a first wind turbine, wherein the first pool is provided with a high pressure air inlet, a medium pressure air outlet, a pressure relief port, a water return port, a water supply port and a water supply port, and the high pressure gas The tank is connected to the first pool through a high-pressure air pipe, and the first pool is connected to the water inlet of the first turbine group through a water supply pipe, and the water outlet of the first turbine group passes through the return pipe and the first pool Connected, the first turbine group drives the first wind turbine; the second energy storage power unit includes an intermediate pressure gas tank, two or more second water pools, a second water turbine unit, and a second wind turbine, wherein the second pool is provided with a medium pressure air inlet, a pressure relief port, a water return port, a water supply port and a water supply port, wherein the medium pressure gas tank is connected to the second pool through a high pressure gas pipe, a second water pool is connected to the water inlet of the second turbine unit through a water supply pipe, a water outlet of the second water turbine unit is connected to the second water pool through a water return pipe, and the second water turbine unit drives the second wind power The user air supply tank is in communication with the high pressure gas tank, and the high pressure gas tank is connected to the medium pressure gas tank through a high pressure gas pipe, and the first water pool is connected to the medium pressure gas tank through a medium pressure gas pipe. The power generation equipment can be a power plant. When the user uses a small power plant to generate surplus power at night, the high-pressure air pump is started, and the air source is continuously compressed into the main high-pressure gas tank for storage, thereby realizing the conversion of the electric energy to the molecular potential energy of the high-pressure gas. The main high-pressure gas tank transports high-pressure gas to remote remote users through the main high-pressure gas transmission pipeline; these remote users who are short of electricity can use the high-pressure gas in the user's gas supply tank to generate electricity, thus solving the problem of power shortage .

 The beneficial effects of the present invention compared to the prior art are:

The power supply device of the present invention may be a regional power grid or a power plant. In the case where the user uses a small power plant to generate power surplus at night, the high-pressure air pump is started, and the air source is continuously compressed into the main high-pressure gas tank for storage, thereby realizing the electric energy to the high voltage. The conversion of the molecular potential energy of the gas; the main high-pressure gas tank transports the high-pressure gas to the remote remote users through the main high-pressure gas transmission pipeline; these remote users who are in short supply can use the high-pressure gas in the pressure-relief equipment to generate electricity, thereby solving The problem of shortage of electricity. In addition, the remote transportation of energy using buried pipelines is safer and more reliable than the overhead high voltage electrical racks, and the cost is lower. DRAWINGS

 1 is a schematic structural view of an energy remote transmission conversion system of the present invention.

 2 is a schematic structural view of a power generating device of Embodiment 1.

 Fig. 3 is a schematic view showing the connection of the user air supply tank and the energy conversion device of the embodiment 2.

 4 is a schematic structural view of an energy conversion device of Embodiment 2. detailed description

 The invention will now be further described with reference to the drawings of the specification.

Example 1

As shown in FIG. 1, a high-pressure gas remote transmission conversion system includes a power supply device 1, a high-pressure gas generating device, a main high-pressure gas delivery pipe 5, and one or more remote users 2. The power supply device 1 may be a regional power grid or a power plant, such as a hydroelectric power plant, a wind power plant, a thermal power plant, etc.; when power is idle at night, these power plants generate surplus power. The high-pressure gas generating device includes a high-pressure air pump 3 and a main high-pressure gas tank 4 connected to the high-pressure air pump 3, the power supply device 1 supplies power to the high-pressure air pump 3, the main high-pressure gas tank 4 and the main high-pressure gas The gas delivery pipe 5 is connected; the high-pressure air pump 3 operates with the surplus power of the power plant, and continuously compresses the air into the main high-pressure gas tank 4 for storage, thereby converting the electric energy into the molecular potential energy of the high-pressure gas. The remote user 2 may be a remote area or an industrial area where power is scarce, each of the remote users 2 is provided with more than one step-down device and more than one user collection gas tank 22; the step-down device may be The pressure reducing device and the user air supply tank 21, the pressure reducing device of the embodiment is a user air supply tank 21, and the pressure reducing devices are arranged according to the power demand of the area, and the pressure reducing device passes through the branch high pressure gas delivery pipe 24 Connected to the main high-pressure gas delivery pipe 5, the branch high-pressure gas delivery pipe 24 is provided with a pressurizing device 23 and a control trick 6; the user collecting gas tank 22 passes through the high-pressure gas recovery pipe 25 and the main The high-pressure gas delivery pipe 5 is connected, and the high-pressure gas recovery pipe 25 is provided with a pressurizing device 23 and a control pedal 6. As shown in FIG. 2, the step-down device is connected to the power generating device 7. In the present invention, the power generating device 7 includes a wind power generator 73, a water tank 71, and a water turbine unit 72, and the pressure reducing device 21 passes through a high-pressure air pipe and a device. The water tank 71 is connected, the water tank 71 is connected to the water turbine unit 72 through a water supply pipe 74, and the water turbine unit 72 is linked with the rotor of the wind power generator 73. The wind power generator 73 is installed to solve the problem of power consumption in a remote area. The development trend, but the wind turbine 73 is relatively restricted by the environment. When there is no wind or the wind speed is low, the wind turbine 73 cannot operate to generate electricity; The electric power generated by the surplus place is converted and transported, and finally applied to the wind power supply device 1 to assist the wind power generator 73 to generate electricity, thereby converting the molecular potential energy of the high pressure gas into electric energy.

 The remote user 2 delivers the remaining high pressure gas to the user collection gas tank 22, and the high pressure gas in the user collection gas tank 22 is returned to the main high pressure gas delivery pipe 5 through the high pressure gas recovery pipe to realize energy recovery and energy conservation. The main high-pressure gas delivery pipe 5 is provided with a plurality of control tips 6 . After the two adjacent control gates 6 are closed, a high-pressure gas storage unit is formed between the adjacent two steps, the high-pressure gas is formed. The gas storage unit can deliver high pressure gas to a remote user 2 separately. When a high pressure gas leak occurs on the main high pressure gas delivery pipe 5, the control gate 6 of the section is closed to secure the main high pressure gas delivery pipe 5.

 After the high-pressure air pump 3 is powered by the power supply device 1, the air is compressed into the main high-pressure gas tank 4 for storage; the main high-pressure gas tank 4 discharges the high-pressure gas into the main high-pressure gas delivery pipe 5, using the main high-pressure gas delivery pipe 5 Remote transmission of high pressure gas; remote user 2 introduces high pressure gas in main high pressure gas delivery pipe 5 into the step-down device through branch high pressure gas delivery pipe 24 for storage; when remote user 2 needs to generate electricity, the high voltage in the step-down device The gas is released and the work is performed on the power generation equipment to realize the energy conversion, the waste of the surplus power of the power supply equipment 1 and the shortage of the power of the remote user 2 are solved.

Example 2

As shown in FIG. 1, a high pressure gas delivery system includes a power generation device 1, a high pressure gas generating device, a main high pressure gas delivery conduit 5, and one or more remote users 2. The power plant 1 may be a power plant, such as a hydroelectric power plant, a wind power plant, a thermal power plant, etc.; when power is idle at night, these power plants generate surplus power. The high-pressure gas generating device includes a high-pressure air pump 3 and a main high-pressure gas tank 4 connected to the high-pressure air pump 3, the power generating device 1 supplies power to the high-pressure air pump 3, the main high-pressure gas tank 4 and the main high-pressure gas The gas delivery pipe 5 is connected; the high-pressure air pump 3 operates with the surplus power of the power plant, and continuously compresses the air into the main high-pressure gas tank 4 for storage, thereby converting the electric energy into the molecular potential energy of the high-pressure gas. The remote user 2 may be a remote area or an industrial area where power is scarce, and each of the remote users 2 is provided with more than one user air supply tank 21 and one or more user collection gas tanks 22; these user air supply tanks 21 Arranged according to the power demand of the area, the user gas supply tank 21 is connected to the main high-pressure gas transmission pipeline 5 through a branch high-pressure gas delivery pipeline 24, and the branch high-pressure gas transmission pipeline 24 is provided with supercharging. The device 23 and the control module 6; the user collection gas tank 22 is connected to the main high pressure gas delivery pipe 5 through a high pressure gas recovery pipe 25, the high pressure gas recovery A pressurized device 23 and a control pedal 6 are provided on the duct 25. As shown in FIG. 2, the user air supply tank 21 is connected to the energy conversion device 7, thereby converting the molecular potential energy of the high pressure gas into electric energy.

 The remote user 2 delivers the remaining high pressure gas to the user collection gas tank 22, and the high pressure gas in the user collection gas tank 22 is returned to the main high pressure gas delivery pipe 5 through the high pressure gas recovery pipe to realize energy recovery and energy conservation. The main high-pressure gas delivery pipe 5 is provided with a plurality of control tips 6 . After the two adjacent control gates 6 are closed, a high-pressure gas storage unit is formed between the adjacent two steps, the high-pressure gas is formed. The gas storage unit can deliver high pressure gas to a remote user 2 separately. When a high pressure gas leak occurs on the main high pressure gas delivery pipe 5, the control gate 6 of the section is closed to secure the main high pressure gas delivery pipe 5.

 As shown in Figures 3 and 4, the energy conversion device includes a first energy storage power generation unit 81 and a second energy storage power generation unit 82, and more energy storage power generation units may be provided according to actual conditions. The first energy storage power generation unit 81 includes a high pressure gas tank 811, three first water tanks 812, a first water turbine unit 813, and a first wind power generator 814; the user air supply tank 21 is connected to the high pressure gas tank 811. The first water tank 812 is provided with a high pressure air inlet, a medium pressure air outlet, a pressure relief port, a water return port, a water supply port and a water supply port, and the pressure release port is provided with a pressure relief port; 811 is connected to the first water tank 812 through a high pressure air pipe 6, the first water tank 812 is connected to the water inlet of the first water turbine unit 813 through a water supply pipe 4, and the water outlet of the first water turbine unit 813 passes through a water return pipe 85 is in communication with the first pool 812, and the first turbine unit 813 drives the first wind turbine 814. The second energy storage power unit 82 includes an intermediate pressure gas tank 821, three second water pools 822, a second water turbine unit 823, and a second wind power generator 824; the second water tank 822 is provided with a medium pressure air inlet, a pressure relief port, a water return port, a water supply port and a water supply port, wherein the pressure relief port is provided with a pressure relief port; the medium pressure gas cylinder 821 is connected to the second water pool 822 through a high pressure gas pipe 86, the second water pool 822 Connected to the water inlet of the second turbine unit 823 through a water supply pipe 84, the drain port of the second turbine unit 823 is in communication with the second pool 822 through a return pipe 85, and the second turbine unit 823 drives the Second wind turbine 824. The high pressure gas tank 811 is in communication with the intermediate pressure gas tank 821 through a high pressure gas pipe 86, and the first water tank 812 is in communication with the intermediate pressure gas tank 821 through a medium pressure gas pipe. A water level gauge and a pressure gauge are disposed on the first pool 812 and the second pool 822; and the water supply pipe 84, the return pipe 85, the high pressure gas pipe 86 and the medium pressure gas pipe are provided with control tips.

The working principle of the energy conversion device: the first energy storage power generation unit 81 and the second energy storage power generation unit 82 can work simultaneously; when the first energy storage power generation unit 81 is working, there may be more than one first The pool 812 is working at the same time, that is, a plurality of pools work on the first turbine unit 813; the first pool 812 in the working state is set as the working pool, and the unoperated pool is set as the reserve pool. Before the work, the working pool is filled with water, and the spare pool is empty; during operation, the high pressure gas tank 811 compresses the constant pressure high pressure gas into the working pool through the high pressure gas pipe 86, and the high pressure gas accumulates in the working pool and Producing high pressure, the high pressure gas in this part has a large molecular potential energy, which can exert great pressure on the water in the working pool; release the water in the working pool at the time or place where the electricity is scarce, under the pressure of high pressure gas The working pool can spray a water column with a large kinetic energy to the first turbine unit 813, and the water column pushes the turbine unit to rotate, thereby completing the conversion of the molecular potential energy to the mechanical energy; finally, the first turbine unit 813 drives the wind power generator to generate electricity, thereby completing the mechanical energy to the electrical energy. Conversion. The water discharged by the turbine unit is returned to the reserve pool through the return pipe 75. After the water in the working pool is completely used up, the remaining medium pressure gas will enter the medium pressure gas pipe through the medium pressure gas pipe, and finally the low pressure gas remaining in the working pool. It will be discharged to the atmosphere through the pressure relief port. The spare pool filled with water will become the new working pool and the above steps will be repeated to complete the energy conversion. The working principle of the second energy storage power generation unit 82 is the same as that of the first energy storage power generation unit 81, and will not be described in detail herein.

 After the high-pressure air pump 3 of the present invention is powered by the power generating device 1, the air is compressed into the main high-pressure gas tank 4 for storage; the main high-pressure gas tank 4 releases the high-pressure gas into the main high-pressure gas conveying pipe 5, and the main high-pressure gas conveying pipe is utilized. 5 remotely conveying the high pressure gas; the remote user 2 introduces the high pressure gas in the main high pressure gas delivery pipe 5 into the user gas supply tank 21 through the branch high pressure gas delivery pipe 24 for storage; when the remote user 2 needs to generate electricity, the user is provided The high-pressure gas in the gas tank 21 is released and the energy conversion device is operated to realize the energy conversion, and the waste of the surplus power of the power generation equipment 1 and the shortage of the power of the remote user 2 are solved.

Claims

Claim

A high-pressure gas remote transfer conversion system, comprising: a power supply device, a high-pressure gas generating device, a main high-pressure gas delivery pipe, and one or more remote users; the high-pressure gas generating device includes a high-pressure gas pump and the high-voltage pump a main high pressure gas tank connected to the air pump, the power supply device supplies power to the high pressure air pump, the main high pressure gas tank is connected to the main high pressure gas delivery pipeline; each of the remote users is provided with more than one pressure relief device, The step-down device is connected to the main high-pressure gas delivery pipe through a branch high-pressure gas delivery pipe; the step-down device is connected to the power generation device.

2. The high pressure gas remote transfer conversion system according to claim 1, wherein: the main high pressure gas delivery pipe is provided with a plurality of control tips.

 3. The high-pressure gas remote transmission conversion system according to claim 1, wherein: the bypass high-pressure gas delivery pipeline is provided with a boosting device and a control trick.

 4. The high-pressure gas remote transmission conversion system according to claim 1, wherein: said remote user further comprises one or more user collection gas tanks, said user collection gas tank passing through said high pressure gas recovery pipeline and said A main high pressure gas delivery pipe is connected, and the high pressure gas recovery pipe is provided with a pressurizing device and a control trick.

 5 . The high-pressure gas remote transmission conversion system according to claim 1 , wherein: the power generation device comprises a wind power generator, a water tank and a water turbine unit, and the pressure reduction device is connected to the water tank through a high-pressure air pipe. The water tank is connected to the water turbine unit through a water supply pipe, and the water turbine unit is interlocked with a rotor of the wind power generator.

 6. A high pressure gas remote transfer conversion system, characterized in that: the high pressure system delivery system comprises a power supply device, a high pressure gas generating device, a main high pressure gas delivery pipe and more than one remote user; the high pressure gas generating device The utility model comprises a high-pressure air pump and a main high-pressure gas tank connected to the high-pressure air pump, wherein the power supply device supplies power to the high-pressure air pump, and the high-pressure gas tank is connected to the main high-pressure gas transmission pipeline; each of the remote users is provided with More than one step-down device, wherein the step-down device is connected to the main high-pressure gas delivery pipe through a branch high-pressure gas delivery pipe; the step-down device is connected to the power generation device;

 After the high-pressure air pump is powered by the power supply equipment, the air is compressed into the main high-pressure gas tank for storage;

The main high pressure gas tank releases high pressure gas into the main high pressure gas transmission pipeline, using the main high pressure gas The conveying pipeline carries out remote transportation of high pressure gas;

 The remote user introduces the high-pressure gas in the main high-pressure gas transmission pipeline into the step-down equipment through the branch high-pressure gas transmission pipeline for storage;

 The high-pressure gas in the step-down device is released and the power generation device is operated to generate electricity, which solves the problem of waste of surplus power of the power supply device and shortage of power for remote users.

 7. The application of a high pressure gas remote transfer conversion system according to claim 6, wherein: the main high pressure gas delivery pipe is provided with a plurality of control tips, and a high pressure gas is formed between the two control tips. The storage unit, the high pressure gas storage unit can separately deliver high pressure gas to a remote user.

8. The application of a high pressure gas remote transfer conversion system according to claim 7, wherein: when a high pressure gas leak occurs on the main high pressure gas delivery pipe, the control gate of the section is closed to ensure the main high pressure gas delivery pipe. Security.

 9. The application of a high pressure gas remote transfer conversion system according to claim 6, wherein: said remote user further comprises more than one user collecting gas tank, said user collecting gas tank passing through a high pressure gas recovery pipeline and The main high pressure gas delivery pipeline is connected; the remote user delivers the remaining high pressure gas to the user collection gas tank, and the high pressure gas in the user collection gas tank is returned to the main high pressure gas delivery pipeline through the high pressure gas recovery pipe.

 10 . The application of a high-pressure gas remote transmission conversion system according to claim 6 , wherein: the power generation device comprises a wind power generator, a water tank and a water turbine unit, and the pressure reduction device passes through a high pressure air pipe and the water tank. 10 . Connected, the water tank is connected to the water turbine unit through a water supply pipe, and the water turbine unit is linked with the rotor of the wind power generator.

 A method for remotely transferring high-pressure gas, characterized in that: high-pressure gas is remotely transported by a pipe, and a power generating device is disposed at a destination, and the high-pressure gas is made to perform power generation to the power generating device.

The method for remotely transferring high-pressure gas according to claim 11, wherein: the power generating device comprises a wind power generator, a water tank and a water turbine unit, and the pressure reducing device is connected to the water tank through a high-pressure air pipe. The water tank is connected to the water turbine unit through a water supply pipe, and the water turbine unit is interlocked with a rotor of the wind power generator.

13. A system for realizing remote energy storage power generation, comprising: a power generation device, a high pressure gas generating device, a main high pressure gas delivery pipe, and one or more remote users; said high pressure gas generating device comprising a high pressure air pump and said a high-pressure gas pump connected to a high-pressure gas pump, the power generation The device supplies power to the high-pressure air pump, and the main high-pressure gas tank is connected to the main high-pressure gas transmission pipeline; each of the remote users is provided with more than one user air supply tank, and the user air supply tank passes the branch high voltage a gas delivery conduit is connected to the main high pressure gas delivery conduit; the user gas supply tank is connected to the energy conversion device;

The energy conversion device includes a first energy storage power generation unit and a second energy storage power generation unit, the first energy storage power generation unit including a high pressure gas tank, two or more first water pools, a first water turbine unit, and a first wind power generation The first pool is provided with a high pressure air inlet, a medium pressure air outlet, a pressure relief port, a water return port, a water supply port and a water supply port, and the high pressure gas tank is connected to the first pool through a high pressure gas pipe. The first water pool is connected to the water inlet of the first water turbine unit through a water supply pipe, and the water outlet of the first water turbine unit communicates with the first water pool through a return water pipe, and the first water turbine unit drives the first water tank a wind power generator; the second energy storage power unit comprises an intermediate pressure gas tank, two or more second water tanks, a second water turbine unit and a second wind power generator, wherein the second water tank is provided with a medium pressure air inlet, a pressure relief port, a water return port, a water supply port and a water supply port, wherein the medium pressure gas tank is connected to the second water pool through a high pressure gas pipe, and the second water pool is connected to the water inlet of the second water turbine unit through a water supply pipe a drain port of the second turbine unit is in communication with the second pool through a return pipe, the second turbine group drives the second wind power generator; the user air supply tank is in communication with the high pressure gas tank, The high pressure gas tank is in communication with the medium pressure gas tank through a high pressure gas pipe, and the first water tank is in communication with the medium pressure gas tank through a medium pressure gas pipe.

A system for realizing remote energy storage power generation according to claim 13, wherein: said first energy storage power generation unit comprises a total of three first water pools; and said second energy storage power generation unit comprises a total of three Two pools.

The system for realizing remote energy storage power generation according to claim 13, wherein: a pressure relief valve is disposed at a pressure relief port of the first water pool, and a pressure relief port is provided at the second water pool. Pressure.

A system for realizing remote energy storage power generation according to claim 13, wherein: the first pool and the second pool are each provided with a water level gauge and a pressure gauge.

A system for realizing remote energy storage power generation according to claim 13, characterized in that: the water supply pipe, the return pipe, the high pressure gas pipe and the medium pressure gas pipe are provided with control tricks.

A system for realizing remote energy storage power generation according to claim 13, wherein: said main high pressure gas delivery pipe is provided with a plurality of control tips. A system for realizing remote energy storage power generation according to claim 13, wherein: said branch high pressure gas delivery pipe is provided with a boosting device and a control trick.

A system for realizing remote energy storage power generation according to claim 13, wherein: said remote user further comprises more than one user collecting gas tank, said user collecting gas tank passing through said high pressure gas recovery pipeline and said main A high pressure gas delivery pipe is connected, and the high pressure gas recovery pipe is provided with a pressurizing device and a control trick.